Locking nut

ABSTRACT

A nut fastener is provided for locking the nut to prevent inadvertent loosening of the nut. The nut fastener is particularly useful for tightening a wheel onto an axle. The nut fastener includes a nut, a collar and a retaining ring. The nut is unlocked by pushing on an engagement surface of the collar or by riding ratchet teeth over each other. When the collar is released, the collar locks against the nut to resist rotation of the nut.

This application is a continuation of U.S. application Ser. No.14/341,060, filed Jul. 25, 2014, the entire disclosure of which ishereby incorporated by reference. U.S. application Ser. No. 14/341,060claims priority to U.S. Provisional Application No. 61/858,847, filedJul. 26, 2013, which is hereby incorporated by reference herein.

BACKGROUND

The present invention relates generally to internally threaded nuts andmore particularly to a nut that can be locked to prevent the nut fromloosening.

Nuts are known as a versatile component for fastening many differenttypes of parts together. Fundamentally, a nut typically includes innerthreads that are designed to engage corresponding external threads on ashaft. The nut further includes wrench bearing surfaces for rotating thenut with a tool. Accordingly, by rotating the nut, or by rotating theshaft and preventing the nut from rotating, the nut can be tightened orloosened on the shaft. Nuts are also typically provided with a pressuresurface to apply longitudinal force to an apparatus.

One problem with conventional nuts is that they may inadvertently loosenduring use. This commonly occurs when the apparatus that the nut isattached to experiences vibrations during use of the apparatus.Vibrations occur for numerous reasons and usually cannot be controlledby the designer, manufacturer or operator of an apparatus. For example,vibrations can be caused by internal forces necessary for the apparatusto function, such as an internal combustion engine or electric motor, orcan be caused by external forces during use of the apparatus, such as avehicle bouncing up and down as it travels over road. Vibrations cancause a nut to spontaneously loosen by causing fluctuations in thetension of the threaded engagement between the nut and the shaft.Because a nut requires more torque to tighten it than to loosen it, thenut seeks a lower tension state by spontaneously loosening when there issufficient vibration to allow the nut to overcome whatever resistancethere may be to loosening.

Various systems have been designed to prevent nuts from loosening afterbeing initially tightened. A common way to address this problem is toincrease the friction that the nut must overcome before loosening. Oneof the simplest approaches to increase friction is to provide the nutwith a large pressure face that contacts the apparatus and applieslongitudinal force to the apparatus. By increasing the size of thepressure face, the friction between the nut and the apparatus increases,and because the nut must overcome this friction to loosen, the nut ismore resistant to loosening. Friction can be increased even further byproviding protrusions on the pressure face that dig into the apparatuswhen the nut is tightened. Another way to reduce loosening of nuts is toadd an expandable washer between the pressure face of the nut and theapparatus. Expandable washers absorb some of the fluctuations in tensionof the fastener engagement so that the tension on the nut is moreuniform. Thus, the nut is somewhat isolated from the vibrations and doesnot experience the full fluctuations in tension that it normally wouldexperience. Another way to reduce loosening of nuts is to apply anadhesive or other material between the threads of a nut and the shaft.Depending on the type of material used, the result can be to essentiallyglue the nut and the shaft together to prevent relative movement or toincrease the friction that the nut must overcome to loosen.

One problem with many solutions to nut loosening is that the nut canstill loosen if enough vibrations occur to overcome the increasedresistance to loosening. In other words, many approaches rely onincreasing the resistance to loosening but do not provide a positivelocking feature. Another problem with many solutions is that they alsoincrease the amount of torque required to tighten the nut. This is aparticular problem in applications where a precise amount of torque isrequired on the fastener to achieve a specified longitudinal force onthe apparatus. Many solutions are not desirable in this type ofapplication because the increased torque caused by a washer, adhesive orother friction enhancement feature is unpredictable and makes itdifficult to achieve the precise longitudinal force that is required.

One particularly demanding application for nuts is axle nuts that attachthe wheel hub of a vehicle to the axle. Foremost, axle nuts are acritical safety component in a vehicle because if an axle nut loosens,the wheel hub will first begin to wobble erratically and make itdifficult to control the vehicle, and if the axle nut fully loosens, thewheel hub will fall off the vehicle, making control even moreproblematic. Another concern involving axle nuts is that thelongitudinal force applied by the nut to the apparatus is typically usedto preload the wheel bearings. The preload that is applied to the wheelbearings is required to be within a narrow tolerance to ensure that thebearings rotate properly and do not wear out prematurely. As a result,the torque that is applied to the axle nut must be reliably translatedinto longitudinal force without the unpredictability of other frictionenhancement designs. Another concern is that extreme amounts of torqueare applied to axle nuts since a single nut is usually used to fastenthe wheel to a vehicle. Thus, the axle nut must be robust and anylocking feature must also be sufficiently robust. In other wheel hubapplications, the bearings may require a specified end play instead ofpreload. While this application does not require the higher torquesettings that preloaded bearings typically require, precise setting andretention of the end play is still a critical function of the axle nut.

Accordingly, the inventor believes it would be desirable to provide animproved locking nut.

SUMMARY

A nut fastener is described for locking a nut. The nut fastener isprovided with a retaining ring, a collar, a spring, and a nut. Theretaining ring is rotationally fixed to a threaded shaft. The collar isrotationally fixed to the retaining ring. The nut is rotationally fixedto the collar when the spring biases the collar away from the retainingring. When the collar is pushed toward the retaining ring to compressthe spring, the nut becomes unlocked and can rotate relative to thecollar, retaining ring and the threaded shaft. Additional details andadvantages are described below in the detailed description.

The invention may include any of the following aspects in variouscombinations and may also include any other aspect described below inthe written description or in the attached drawings.

BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWINGS

The invention may be more fully understood by reading the followingdescription in conjunction with the drawings, in which:

FIG. 1 is a top plan view of a nut fastener;

FIG. 2 is a side cross-sectional view of the nut fastener in a lockedposition;

FIG. 3 is a side cross-sectional view of the nut fastener in an unlockedposition;

FIG. 4 is a bottom plan view of a nut;

FIG. 5 is a bottom plan view of a collar;

FIG. 6 is a top plan view of a retaining ring;

FIG. 7 is a side perspective view of a wave spring;

FIG. 8 is a top plan view of another embodiment of a retaining ring;

FIG. 9 is a side cross-sectional view of another embodiment of a nutfastener;

FIG. 10 is a top plan view of another embodiment of a nut;

FIG. 11 is a top plan view of another embodiment of a nut fastener;

FIG. 12 is a side cross-sectional view of the nut fastener of FIG. 11;

FIG. 13 is a top perspective view of another embodiment of a nutfastener;

FIG. 14 is a side cross-sectional view of the nut fastener of FIG. 13;

FIG. 15 is a perspective view of another embodiment of a collar;

FIG. 16 is a perspective view of another embodiment of a nut;

FIG. 17 is a perspective view of another embodiment of a retaining ring;

FIGS. 18A-18D are perspective views of another embodiment of a nutfastener;

FIGS. 19A-19D are views of the nut fastener, showing an initial positionwith a free spinning region;

FIGS. 20A-20B are views of the nut fastener, showing an intermediateposition with the ratchet teeth at least partially engaged;

FIGS. 21A-21C are views of the nut fastener, showing a final positionwith the ratchet teeth and torque bearing surfaces fully engaged;

FIG. 22 is an enlarged view of a ratchet tooth on the nut;

FIG. 23 is an enlarged view of a ratchet tooth on the collar;

FIGS. 24A-24D are perspective views of the nut;

FIGS. 25A-25D are perspective views of the collar;

FIGS. 26A-26D are perspective views of the retaining ring;

FIGS. 27A-27B are views of the first spring; and

FIGS. 28A-28B are views of the second spring.

DETAILED DESCRIPTION

Referring now to the figures, a nut fastener 10 is shown. The nutfastener 10 may include a retaining ring 20, a collar 50, a nut 70, anda spring 90, 92. The retaining ring 20 is shown by itself in FIGS. 6 and8 and in cross-section in FIGS. 2-3. The retaining ring 20 includes apressure surface 22 that is designed to contact an apparatus that thenut fastener 10 is attached to and apply longitudinal force from the nutfastener 10 to the apparatus. The retaining ring 20 also includes aninner tab 24, or first rotational retaining member 24, that is designedto engage with a slot in a threaded shaft to prevent rotation betweenthe retaining ring 20 and the shaft. The inner diameter 26 of theretaining ring 20 adjacent the pressure surface 22 provides clearancefor the threaded shaft and for the retaining member 78 of the nut 70. Afirst longitudinal retaining surface 28, or member 28, may be providedadjacent the inner diameter 26. The first longitudinal retaining surface28 may be angled so that it is facing the pressure surface 22. A firsttorque bearing surface 30 may be provided adjacent the firstlongitudinal retaining surface 28. The first torque bearing surface 30may be angled so that it is facing away from the pressure surface 22.The outer diameter 32 of the retaining ring 20 may be slightly largerthan the outer diameter of the collar 50 so that the outer diameter 32of the retaining ring 20 is the largest diameter of the nut fastener 10.The outer diameter 32 may also be provided with opposing flat sides 34that are spaced apart approximately the same width as the outer diameterof the collar 50. The opposing flat sides 34 may be useful for retainingthe retaining ring 20 with a tool to prevent rotation of the retainingring 20. The retaining ring 20 is also provided with three tabs 36, orsecond rotational retaining members 36, that extend away from the axisof the fastener 10 and are equally spaced around the outer circumferenceof the retaining ring 20. As shown in FIGS. 6 and 8, the flat sides 34may be oriented away from the outer tabs 36 in order to reduce theprofile of the nut fastener 10. The retaining ring 20 may also beprovided with a first slide surface 38 around the outer circumference ofthe retaining ring 20 inward from the outer diameter 32 of the retainingring 20. A fourth stop surface 40 may be provided on an opposite side ofthe retaining ring 20 from the pressure surface 22. As shown, in FIG. 6,the retaining ring 20 may be provided with three spring pockets 42equally spaced around the retaining ring 20. The bottom surface 44 ofeach of the spring pockets 42 may be a first spring abutment surface 44.Preferably, each of the spring pockets 42 is located at one of the outertabs 36 so that the outer surfaces of the tabs 36 wrap around the springpockets 42. As shown in FIG. 8, the retaining ring 20 may alternativelybe provided with a groove 46 in the fourth stop surface 40 so that thebottom 48 of the groove 46 may be a first spring abutment surface 48 inthe form of a ring around the axis of the fastener 10.

The collar 50 is shown by itself in FIG. 5 and in cross-section in FIGS.2-3. The collar 50 is preferably formed as a stamping from a plate sothat the thickness of the collar 50 is generally uniform throughout. Thecollar 50 is provided with a first stop surface 52 and a third stopsurface 54 that are disposed on opposite sides of the collar 50. Thecollar 50 may also be provided with an engagement surface 56 thatextends outward from the wrench bearing surfaces 74 when the nutfastener 10 is assembled. Preferably, the engagement surface 56 and thefirst stop surface 52 are flush with each other. The collar 50 may alsobe provided with a second spring abutment surface 54, which may be thesame surface 54 as the third stop surface 54. The outer circumference ofthe collar 50 may be provided with three first recesses 58, or thirdrotational retaining members 58, that receive the retaining ring tabs36. The first recesses 58 may be formed by bending a portion 60 of thecollar 50 so that the outer diameter of the bent portion 60 extendslongitudinally along the nut fastener 10. The inner surface 62 of thebent portion 60 may provide a second slide surface 62 that guides thecollar 50 along the retaining ring 20. The inner circumference of thecollar 50 may be provided with a plurality of second recesses 64, orfourth rotational retaining members 64. The inner circumference 66 ofthe collar 50 may form a third slide surface 66 that slides along thefourth slide surface 84 of the nut 70.

The nut 70 is shown by itself in FIG. 4 and in cross-section in FIGS.2-3. The nut 70 includes inner threads 72 that are designed to engagewith external threads of a shaft. The nut 70 also includes wrenchbearing surfaces 74 that are designed to be engaged by a tool to rotatethe nut 70. A second stop surface 76 may be provided at the bottom ofthe wrench bearing surfaces 74. The nut 70 may be provided with a flaredportion 78, or second longitudinal retaining member 78. Although theflared portion 78 may be formed and shaped in various ways, onedesirable way to make the flared portion 78 is to initially form theflared portion 78 as a straight extension of the nut 70. Duringassembly, the straight extension may be inserted through the retainingring 20 and the straight extension can be swaged to form the flaredportion 78. The nut 70 may also be provided with a second torque bearingsurface 80 that corresponds to the first torque bearing surface 30 ofthe retaining ring 20. Around the outer circumference, the nut 70 may beprovided with three tabs 82, or fifth rotational retaining members 82,that extend outward from the axis of the fastener 10. The tabs 82 mayextend outward from a fourth slide surface 84 and away from the secondstop surface 76 toward the pressure surface 22 of the retaining ring 20.The tabs 80 extend only along a portion of the fourth slide surface 84so that the collar 50 can disengage from the tabs 82 as describedfurther below.

The springs 90, 92 may be either coil springs 90 as shown in FIGS. 2-3or may be a circular or wave spring 92 as shown in FIG. 7. If coilsprings 90 are used, it is preferable to provide spring pockets 42 inthe retaining ring 20 as shown in FIGS. 2-3 and 6. On the other hand, ifa circular spring 92 is used, a groove 46 in the retaining ring 20 asshown in FIG. 8 is preferred.

In another embodiment of the nut fastener 100, as shown in FIG. 9, thesecond longitudinal retaining member 106 may be a bead 106 that ismachined onto the nut 102. The retaining ring 108 may be provided withan inner diameter 110 that is smaller than the diameter of the nut bead106. In order to assemble this arrangement of the nut fastener 100, thenut bead 106 may be pressed through the inner diameter 110 of theretaining ring 108 until the nut bead 106 passes through the innerdiameter 110 and is received by an undercut groove 112 that is larger indiameter than the nut bead 106. To aid assembly, the inner diameter 110of the retaining ring 108 and the nut bead 106 may be provided withchamfers. As also shown, the first and second torque bearing surfaces114, 104 may be flat and orthogonal to the axis instead of being angled.Although not shown in FIG. 9, a collar 50 and wave spring 92 asdescribed above may be adapted to this particular arrangement of the nutfastener 100.

Turning the FIGS. 10-12, another embodiment of the nut fastener 120 isshown. The nut 122 is shown by itself in FIG. 10 and assembled in thenut fastener 120 in FIGS. 11-12. As shown, one or more of the wrenchbearing surfaces 124 may include a recessed area 126 that exposes theend 130 of the nut tab 128 that faces toward the wrench bearing surfaces74, 126. If desired, the tabs 128 may extend through the recessed areas126 and past the second stop surface 76. The ends 130 of the tabs 128may also be flush with the top surface 132 of the nut 122 and the wrenchbearing surfaces 74, 126. As shown in FIG. 11, one advantage of thisarrangement of the nut fastener 120 is that the nut tabs 128 are visiblefrom the top of the nut fastener 120. The second collar recesses 64 thatare positioned within the recessed area 126 are also visible from thetop of the nut fastener 120. As a result, the operator can visuallyverify that the nut tabs 128 are solidly locked in the second collarrecesses 64 when tightening the nut fastener 120.

As shown in FIG. 12, the collar 50 may have a uniform thicknessthroughout and may be formed by stamping a plate. The collar 50 may havea bent portion 60 that extends longitudinally away from the first stopsurface 52 and toward the retaining ring 134. As shown, the innersurface 62 of the bent portion 60 may fully encompass the entire outercircumference 136 of the retaining ring 134. The retaining ring 134 mayalso be formed without any portion extending out from the inner surface62 of the bent portion 60 of the collar 50. As a result, thisarrangement of the nut fastener 120 provides a compact profile with asmall circumferential shape. The thickness of the retaining ring 134 mayalso be minimized since the longitudinal travel of the collar 50 is notinhibited by any portion of the retaining ring 134.

Accordingly, it is now apparent how the nut fastener 10, 100, 120functions. The nut fastener 10, 100, 120 is initially placed over theend of a threaded shaft so that the inner tab 24 of the retaining ring20, 108, 134 is engaged within a slot in the shaft. This prevents theretaining ring 20, 108, 134 from rotating relative to the shaft. The nut70, 102, 122 is permanently secured to the retaining ring 20, 108, 134by the flared portion 78 or the machined bead 106 of the nut 70, 102,122 which engages the first longitudinal retaining surface 28, 112 ofthe retaining ring 20, 108, 134 and prevents the nut 70, 102, 122 frombeing separated from the retaining ring 20, 108, 134. Likewise, thecollar 50 and the springs 90, 92 are trapped between the nut 70, 102,122 and the retaining ring 20, 108, 134 so that the entire nut assembly10, 100, 120 is permanently attached together in an integrated nutassembly 10, 100, 120. In order to unlock the nut 70, 102, 122, theengagement surface 56 of the collar 50 must be pushed toward thepressure surface 22. When the engagement surface 56 is pushed, thesecond spring abutment surface 54 of the collar 50 compresses the spring90, 92 against the first spring abutment surface 44, 48 of the retainingring 20, 108, 134. This allows the collar 50 to slide toward theretaining ring 20, 108, 134 along the first slide surface 38 of theretaining ring 20, 108, 134 and the second slide surface 62 of thecollar 50 and/or the third slide surface 66 of the collar 50 and thefourth slide surface 84 of the nut 70, 102, 122. Once the collar 50slides far enough for the second recesses 64 of the collar 50 todisengage from the tabs 82, 128 of the nut 70, 102, 122, the nut 70,102, 122 becomes unlocked and can rotate relative to the threaded shaft,the retaining ring 20, 108, 134 and the collar 50. The longitudinaltravel of the collar 50 is limited in the disengagement direction by thethird stop surface 54 of the collar 50 and the fourth stop surface 40 ofthe retaining ring 20, 108, 134. However, the nut tabs 82, 128 and thesecond collar recesses 64 may disengage before the third and fourth stopsurfaces 54, 40 contact. In the engagement direction, the longitudinaltravel of the collar 50 is limited by the first stop surface 52 of thecollar 50 and the second stop surface 76 of the nut 70, 102, 122.

When the engagement surface 56 is flush with the first stop surface 52of the collar 50, the engagement surface 56 may be easily pushed by theend of the tool that is used to engage the wrench bearing surfaces 74,124. Thus, for example, when a torque socket is used, the nut assembly10, 100, 120 can be unlocked by simply sliding the torque socket ontothe wrench bearing surfaces 74, 124 and pushing the torque socketagainst the engagement surface 56. The torque tool can then be turned torotate the nut 70, 102, 122. Torque from rotating the nut 70, 102, 122is translated from the second torque bearing surface 80, 104 of the nut70, 102, 122 to the first torque bearing surface 30, 114 of theretaining ring 20, 108, 134. Since the retaining ring 20, 108, 134 doesnot rotate relative to the threaded shaft, the torque from the nut 70,102, 122 is translated to longitudinal force. The longitudinal force isthen applied by the pressure surface 22 to the apparatus.

When the nut fastener 10, 100, 120 has been tightened to the desiredtorque level, the torque tool is removed from the wrench bearingsurfaces 74, 124. If the end of the torque tool is used to push theengagement surface 56 of the collar 50, removal of the torque tool alsoreleases the collar 50. This allows the springs 90, 92 to bias thecollar 50 toward the nut 70, 102, 122 until the first stop surface 52 ofthe collar 50 contacts the second stop surface 76 of the nut 70, 102,122. As a result, the second collar recesses 64 receive the tabs 82, 128of the nut 70, 102, 122. This creates a positive lock that prevents thenut 70, 102, 122 from loosening because the engagement between the nuttabs 82, 128 in the second collar recesses 64 prevent relative rotationbetween the nut 70, 102, 122 and the collar 50; and the engagementbetween the first collar recesses 58 and the retaining ring tabs 36prevents relative rotation between the collar 50 in the retaining ring20, 108, 134; and the engagement between the retaining ring inner tab 24and the shaft slot prevents relative rotation between the retaining ring20, 108, 134 and the threaded shaft. In a preferred embodiment of thenut fastener 10, 100, 120, the collar 50 may be provided with 36 lockingrecesses 64 and each locking recess 64 may represent 0.002″ of threadedtravel between the nut 70, 102, 122 and the threaded shaft. Thisarrangement may be particularly useful for wheel hub applications thatrequire a specified end play for the bearings, such as 0.001″-0.005″,since the required end play can be essentially dialed-in by adjustingthe nut 70, 102, 122 by a certain number of locking positions 64.

Some of the advantages of the nut fastener 10, 100, 120 are also nowapparent. The nut fastener 10, 100, 120 provides a positive lock betweena threaded shaft and the nut 70, 102, 122. Therefore, even when the nutfastener 10, 100, 120 is subject to vibrations during use, it will notinadvertently loosen since the nut fastener 10, 100, 120 does not relyon merely increasing the resistance force to loosening, but insteadsolidly locks the nut 70, 102, 122 to prevent loosening. The nutfastener 10, 100, 120 is also designed to be robust so that the lockingfeatures cannot be easily broken or overcome. Thus, the nut fastener 10,100, 120 may be particularly useful in applications, such as axle nutswhere extreme torque is applied to the nut. The nut fastener 10, 100,120 also achieves these advantages without causing an increase in torqueneeded to tighten the nut 70, 102, 122, which makes it easier to applyprecise longitudinal force to the apparatus, such as when the nut 70,102, 122 is used to preload wheel bearings. The nut fastener 10, 100,120 is also useful in setting precise end play for wheel bearings andother applications. The friction surface between the first and secondbearing surfaces 30, 80, 104, 114 of the retaining ring 20, 108, 134 andthe nut 70, 102, 122 may also be optimized to reduce the friction thatoccurs during tightening of the nut 70, 102, 122.

Turning to FIGS. 13-17, another embodiment of the nut fastener 140 isshown. Those of ordinary skill in the art will recognize that a numberof features of the nut fastener 140 are equivalent to features alreadydescribed above. Therefore, the entire description provided above neednot be repeated for an understanding of the nut fastener 140 shown inFIGS. 13-17. As shown in FIGS. 13 and 14, the nut fastener 140 includesa collar 150, nut 170, retaining ring 200, and spring 230. The nut 170may be made by hot forging, and the collar 150 and retaining ring 200may be made by stamping. However, other manufacturing processes may alsobe used.

As shown in FIG. 15, the collar 150 includes a first stop surface 152,third stop surface 154, engagement surface 156, first recesses 158, orthird rotational retaining members 158, bent portion 160, second slidesurface 162, first ratchet teeth 164, or fourth rotational retainingmembers 164, third slide surface 166, locking surfaces 168, and inclinedsurfaces 169.

As shown in FIG. 16, the nut 170 includes inner threads 172, wrenchbearing surfaces 174, second stop surface 176, bead 178, or secondlongitudinal retaining member 178, second torque bearing surface 180,second ratchet teeth 182, or fifth rotational retaining members 182,fourth slide surface 184, recessed wrench bearing surfaces 186, recessedareas 188, tab end 190, top surface 192, locking surfaces 194, inclinedsurfaces 195, and tab 196.

As shown in FIG. 17, the retaining ring 200 includes a pressure face202, inner tab 204, inner diameter 206, undercut 208, or firstlongitudinal retaining surface 208, first torque bearing surface 210,outer diameter 212, or first slide surface 212, tabs 214, or secondrotational retaining members 214, fourth stop surface 216, groove 218,and bottom 220 of groove 218, or first spring abutment surface 220.

While the nut fastener 140 is similar to the nut fasteners 10, 100, 120described above, the nut fastener 140 includes some distinct featuresthat may provide additional advantages. For example, the nut 170 and thecollar 150 lock together through ratchet teeth 182, 164 on the nut 170and the collar 150. Each of the nut ratchet teeth 182 face downward andhave a locking surface 194 and an inclined surface 195. Each of thecollar ratchet teeth 164 face upward and have a corresponding lockingsurface 168 and inclined surface 169. As a result, when the nut 170 istightened, the collar 150 does not need to be independently pushed tounlock the nut fastener 140. Instead, the inclined surfaces 195, 169 ofthe nut ratchet teeth 182 and collar ratchet teeth 164 slide againsteach other when the nut 170 is rotated in the tightening direction andforce the collar 150 against the spring 230. This may be more intuitiveto the operator and may prevent damage to the nut fastener 140 if anoperator inadvertently attempts to tighten the nut 170 without activelypushing against the collar 150. However, after the nut 170 is tightened,the locking surfaces 194, 168 of the nut ratchet teeth 182 and collarratchet teeth 164 will engage each other and prevent the nut 170 fromrotating in the loosening direction. Thus, in order to loosen the nut170, the collar 150 must be independently pushed against the spring 230in order to release the ratchet teeth 182, 164.

As shown in FIG. 16, at least one of the ratchet teeth 182 on the nut170 may be on end of the tab 196 that extends through the recessed area188 so that the end 190 of the tab 196 may be flush with the top surface192 of the nut 170. This may provide the operator with a visualindication of the locking arrangement between the nut 170 and the collar150.

As shown in FIGS. 13, 14 and 17, the retaining ring 200 may be made sothat the outer diameter 212 fits within the bent portion 160 of thecollar 150. Thus, the outer diameter 212 of the retaining ring 200 actsas the first slide surface 212 and slides along the second slide surface162 of the collar 150. The tabs 214 of the retaining ring 200 may extendoutward from the outer diameter 212 and may fit within the firstrecesses 158 of the collar 150. Thus, no portion of the retaining ring200 extends outward from the collar 150 and is generally not visibleduring tightening and loosening of the nut fastener 140. Like theretaining ring 20 shown in FIG. 8, the retaining ring 200 may have agroove 218 for the spring 230 which extends circumferentially around thenut fastener 140. However, in order to reduce the diameter of the nutfastener 140, a coiled spring 230 may be used between the retaining ring200 and collar 150.

As shown in FIGS. 14 and 15, the underside 165 of the ratchet teeth 164of the collar 150 may act as the opposing surface for the spring 230.The third stop surface 154 of the collar 150 may be separate from theunderside 165 of the ratchet teeth 164 and may be located radiallyoutward therefrom. The engagement surface 156 of the collar 150 may alsobe a flat ring located radially outward from the ratchet teeth 164.

It is now apparent that the nut fastener 140 functions in a similarmanner to the nut fasteners 10, 100, 120 described above and has similaradvantages. However, the differences described above and shown in thefigures may provide desirable improvements over the previously describednut fasteners 10, 100, 120.

Turning to FIGS. 18A-28B, another embodiment of a nut fastener 300 isshown. Those of ordinary skill in the art will recognize that some ofthe individual features of the nut fastener 300 are similar to featuresalready described above. Therefore, the entire description providedabove need not be repeated for an understanding of the nut fastener 300shown in FIGS. 18A-28B. Although the basic operation of the nut fastener300 functions in a similar manner to the nut fasteners described above,the nut fastener 300 provides additional advantages that may bedesirable. As shown in FIGS. 18A-18D, the nut fastener 300 may include anut 310 (FIGS. 24A-24D), a collar 340 (FIG. 25A-25D), a retaining ring370 (FIGS. 26A-26D), a first spring 396 (FIGS. 27A-27B), and a secondspring 398 (FIG. 28A-28B). The nut 310 and retaining ring 370 may bemade by hot forging, and the collar 340 may be made by stamping.However, other manufacturing processes may also be used.

As shown in FIGS. 24A-24D, the nut 310 may include inner threads 312,wrench bearing surfaces 314, a bead 316, or second longitudinalretaining member 316, a second torque bearing surface 318, secondratchet teeth 320, or fifth rotational retaining members 320, firstinclined surfaces 322, second inclined surfaces 324, and a bottom 328,or fourth spring abutment surface 328.

As shown in FIGS. 25A-25D, the collar 340 may include first ratchetteeth 342, or fourth rotational retaining members 342, first inclinedsurfaces 344, second inclined surfaces 346, an underside 348 of theratchet teeth 342, or second spring abutment surface 348, an engagementsurface 350, first recesses 352, or third rotational retaining members352, ribs 354, or fourth longitudinal retaining members 354, a bentportion 356, an inner surface 358 of the bent portion 356, or secondslide surface 358, and an inner diameter 360.

As shown FIG. 26A-26D, the retaining ring 370 may include a pressuresurface 372, an inner tab 374, or first rotational retaining member 374,an inner diameter 376, an undercut groove 378, or first longitudinalretaining surface or member 378, a first torque bearing surface 380, anouter circumference 382, or first slide surface 382, tabs 384, or secondrotational retaining members 384, a bottom side 386 of the tabs 384, orthird longitudinal retaining member 386, a top surface 388, or firstspring abutment surface 388, and an inner ledge 390, or third springabutment surface 390.

As shown FIGS. 19A-19D, one feature of the nut fastener 300 is that thenut 310 can free spin relative to the collar 340 during initialthreading of the nut 310 onto the shaft so that the nut fastener 300 iseasier to install. In FIGS. 19A-19D, the nut fastener 300 is illustratedin its initial position before being threaded onto a shaft. As shown,the first and second ratchet teeth 342, 320 of the collar 340 and thenut 310 are disengaged from each other when the bead 316 of the nut 310is engaged with the undercut 378 of the retaining ring 370 and the ribs354 of the collar 340 are engaged with the bottom side 386 of the tabs384 of the retaining ring 370. In order to provide an initial freespinning stage, the sizing of the spaces 330, 362 between the ratchetteeth 320, 342 and the retaining members 316, 378, 354, 386 has beenadjusted to provide an initial position where the ratchet teeth 320, 342are disengaged from each other. Specifically, the spacing 330 betweenthe nut ratchet teeth 320 and the nut bead 316 are controlled relativeto the spacing 362 between the collar ratchet teeth 342 and the collarribs 354 so that when the nut 310 and the collar 340 are at theiruppermost positions, the ratchet teeth 320, 342 are disengaged from eachother. As a result, this design requires two different stops to limitlongitudinal movement of the nut 310 and the collar 340. The first stop(i.e., the bead 316 and undercut 378) limits movement between the nut310 and the retaining ring 370 and prevents the nut 310 and retainingring 370 from being separated from each other. The second stop (i.e.,the ribs 354 and the bottom side 386 of the tabs 384) limits movementbetween the collar 340 and the retaining ring 370 and prevents thecollar 340 and retaining ring 370 from being separated from each other.Thus, by controlling the positioning of these stops relative to theratchet teeth 320, 342, a free spinning region can be provided where theratchet teeth 320, 342 do not engage each other.

In FIG. 19D, the nut fastener 300 is shown with an alternative fourthlongitudinal retaining member 354. Unlike the rib 354 of FIG. 19C wherethe bottom edge of the collar 340 is bent inwards, the collar 340 ofFIG. 19D has a slot 355 and the bottom edge of the slot 355 is bentinward. The bottom edge surface of the slot 355 which contacts thebottom side 386 of the tab 384 is preferably perpendicular to the axisof nut fastener 300. The bottom side 386 of the tab 384 may also beperpendicular to the axis of the nut fastener 300. This configurationmay be desirable to provide a more consistent stop location between thecollar 340 and the retaining ring 370. As also shown in FIG. 19D, thenut 310 may have a guide surface 368 between the bottom 328 of the nut310 and the bead 316. The guide surface 368 has a diameter that isslightly smaller than the inner diameter of the second spring 398. Thus,the spring 398 seats around the guide surface 368, and the guide surface368 helps to retain spring 398 in place.

FIGS. 20A-20B illustrate the nut faster 300 in an intermediate positionas it is being threaded onto the shaft. As the nut 310 is tightened ontothe shaft, the pressure face 372 of the retaining ring 370 willeventually contact the apparatus, such as a bearing or housing, andstart to apply force to the apparatus. Since the retaining ring 370 canno longer move longitudinally as the nut 310 is tightened, the nut 310will begin to move longitudinally toward the retaining ring 370. Thiscauses the bead 316 of the nut 310 to move away from the undercut 378 ofthe retaining ring 370. As a result, the ratchet teeth 320, 342 of thenut 310 and collar 340 will draw toward each other and begin to engageeach other. As the ratchet teeth 320, 342 engage each other and the nut310 is tightened further, the nut ratchet teeth 320 ride over the collarratchet teeth 342 and push the collar 340 toward the retaining ring 370.This causes the ribs 354 of the collar 340 to move away from the bottomside 386 of the tabs 384 of the retaining ring 370.

As shown in FIGS. 21A-210, when the nut 310 is fully tightened, theratchet teeth 320, 342 of the nut 310 and collar 340 will be fullyengaged with each other. This locks the nut fastener 300 so that theratchet teeth 320, 342 resist loosening of the nut 310. As shown, theratchet teeth 320, 342 are fully engaged when the first and secondtorque bearing surfaces 380, 318 of the retaining ring 370 and the nut310 are engaged with each other. Preferably, the free spinning range isrelatively small, and the ratchet teeth 320, 342 begin to engage eachother after 1.5 rotations or less of the nut 310 on the shaft. Theintermediate range between initial and full engagement of the ratchetteeth 320, 342 may be more than the free spinning range, and ispreferably about one to about three rotations of the nut 310 on theshaft.

As shown in FIGS. 19A-21C and 27A-28B, the nut fastener 300 may also beprovided with two separate springs 396, 398. The first spring 396 may bepositioned between the top surface 388 of the retaining ring 370 andunderside 348 of the ratchet teeth 342. Thus, the first spring 396biases the retaining ring 370 and collar 340 away from each other untilcontact between the ribs 354 of the collar 340 and the bottom side 386of the tabs 384 of the retaining ring 370 stops further travel. Thesecond spring 398 may be positioned between an inner ledge 390 of theretaining ring 370 and the bottom 328 of the nut 310. Thus, the secondspring 398 biases the retaining ring 370 and nut 310 away from eachother until contact between the bead 316 of the nut 310 and undercut 378of the retaining ring 370 stops further travel. One advantage of thesecond spring 398 is that when the nut 310 is in the free spinning rangeduring initial threading of the nut 310 onto the shaft, the secondspring 398 will force the nut 310 away from the retaining ring 370 (andaway from the collar 340 since the collar 340 is retained to theretaining ring 370). This allows the nut 310 to be truly free spinningsince inadvertent contact between the ratchet teeth 320, 342 will beavoided due to the bias of the second spring 398. Although differenttypes of springs are possible, circular, wave springs 396, 398 thatextend around the axis of the fastener 300 are preferred for the firstand second springs 396, 398 to provide balanced spring force and acompact design. As shown in FIGS. 27A-27B, which illustrates the firstspring 396, the springs 396, 398 may have a gap between the ends, or asshown in FIGS. 28A-28B, which illustrates the second spring 398, thesprings 396, 398 may have ends that overlap or may be a continuous ring.As explained above, when the nut 310 is tightened onto the shaft, thenut 310 moves toward the collar 340, which compresses the second spring398. Because the second spring 398 is designed to facilitate the freespinning range of the nut 310 and is not intended to control the tensionbetween the ratchet teeth 320, 342, it is preferred for the bias forceof the second spring 398 to be as small as possible. For example, in theembodiment illustrated in the figures, the bias of the second spring 398counters the bias of the first spring 396, such that the bias of thefirst spring 396 forces the ratchet teeth 320, 342 into engagement, butthe second spring 398 forces the ratchet teeth 320, 342 apart from eachother. Thus, the second spring 398 can affect the tension of the ratchetteeth 320, 342, but it is preferred that the second spring 398 haveminimal influence on the tension of the ratchet teeth 320, 342. Thus,the bias of the first spring 396 is preferably greater than the bias ofthe second spring 398, and more preferably at least two times or fourtimes greater than the bias of the second spring 398.

As shown in FIGS. 22-23, the nut fastener 300 may also be provided withratchet teeth 320, 342 that resist relative rotation between the nut 310and the collar 340. As shown in FIG. 22, the ratchet teeth 320 on thenut 310 may include a first inclined surface 322 that faces thetightening direction and a second inclined surface 324 that faces theloosening direction. Similarly, the collar 340 may include a firstinclined surface 344 that faces the tightening direction and a secondinclined surface 346 that faces the loosening direction. Preferably, theratchet teeth 320, 342 are shaped to allow the ratchet teeth 320, 342 toride over each other in the tightening direction and press the collar340 toward the retaining ring 370 to allow the nut 310 to be rotatedrelative to the collar 340 and the retaining ring 370. The ratchet teeth320, 342 may also be shaped to allow the ratchet teeth 320, 342 to rideover each other in the loosening direction and press the collar 340toward the retaining ring 370 to allow the nut 310 to be rotatedrelative to the collar 340 and the retaining ring 370. It may bedesirable for the shapes of the nut ratchet teeth 320 and the collarratchet teeth 342 to generally match each other so that the nut ratchetteeth 320 seat within the collar ratchet teeth 342 when the ratchetteeth 320, 342 are fully engaged.

Preferably, the torque required for the ratchet teeth 320, 342 to rideover each other is higher in the loosening direction than in thetightening direction. This may be achieved by providing a steeperincline on the second inclined surfaces 324, 346 facing in the looseningdirection than the first inclined surfaces 322, 344 facing in thetightening direction. In other words, the shape of the nut ratchet teeth320 or the collar ratchet teeth 342 is asymmetric. Thus, the nut 310will have less resistance to rotating in the tightening direction butwill have greater resistance to rotating in the loosening direction. Forexample, it may be particularly useful for the torque required to ridethe ratchet teeth 320, 342 over each other in the tightening directionto be high enough that a wrench is required to rotate the nut 310.Although the torque in the tightening direction could be set lower toallow hand tightening, setting the torque higher to require a wrench mayavoid inadvertent movement of the nut 310 during installation which mayprevent misadjustments to sensitive settings like bearing end play inaxle wheels. For example, a torque of at least about 10 ft·lb may bedesirable in the tightening direction before the ratchets 320, 342 willride over each other to allow the nut 310 to rotate. On the other hand,it may be preferable for the torque required to ride the ratchet teeth320, 342 over each other in the loosening direction to be substantiallygreater than in the tightening direction to prevent the nut 310 fromloosening during use due to vibrations, etc. For example, it may bedesirable for the loosening torque required to ride the ratchet teeth320, 342 over each other to be at least three times the tighteningtorque. Thus, the loosening torque (not including thread engagementtorque) may be at least about 40 ft·lb. However, it is preferred thatthe total loosening torque required to loosen the nut 310 (includingboth the thread torque and the ratchet torque) be less than the torquethat would damage the shaft slot, inner tab 374, or other parts of thenut fastener 300. For example, it is preferable that the looseningtorque to ride the ratchet teeth 320, 342 over each other (without thethread torque) be less than about 100 ft·lb. Thus, unlike some nutfasteners which are either destroyed or damage the shaft when they areloosened without releasing the locking mechanism, the nut fastener 300with ratchet teeth 320, 342 can be loosened with a wrench withoutactively pushing on the collar 340 while avoiding damage to the shaftand the nut fastener 300.

Although the nut fastener 300 may be tightened and loosened withoutactively pushing the collar 340 away from the nut 310 to disengage theratchet teeth 320, 342 before rotating the nut 310, an engagementsurface 350 is provided on the collar 340 for this purpose. As shown inFIGS. 18A and 18C, the engagement surface 350 may be a top surface ofthe collar 340 that extends radially outward from the wrench bearingsurfaces 314 and rests at the bottom of the wrench bearing surfaces 314when the ratchet teeth 320, 342 are fully engaged. As shown, it may bedesirable for the engagement surface 350 to be generally flush with thetop of the ratchet teeth 342 of the collar 340. Thus, when theengagement surface 350 is used, the end of the wrench, such as a socket,can be pressed against the engagement surface 350 to longitudinally pushagainst the collar 340. This compresses the spring 396 and causes theratchet teeth 320, 342 to separate from each other. As a result, theratchet teeth 320, 342 will not require any torque to overcome theratchet teeth 320, 342 during tightening and loosening if the teeth 320,342 are fully disengaged, or if only partially disengaged, will requireless torque to ride over each other than if the engagement surface 350is not pressed at all.

One advantage of the nut fastener 300 is the clean outer design of thenut fastener 300 and its small outer profile. This is accomplished inpart by the bent portion 356 of the collar 340 that wraps around theretaining ring 370 and encompasses the outer circumference 382 of theretaining ring 370. The tabs 384 of the retaining ring 370 may also belocated on the outer surface of the retaining ring 370. The recesses 352of the collar 340 may be located on the inside of the bent portion 356to engage with the tabs 384 of the retaining ring 370. Preferably, theinner surface of the bent portion 356 encompasses the entire outercircumference 382 of the retaining ring 370 so that no portion of theretaining ring 370 extends out from the inner surface of the bentportion 356. As shown in FIGS. 23 and 25B, the collar 340 may also bestamped from a plate so that the collar 340 has a uniform thicknessthroughout, including the ratchet teeth 342. As shown in FIGS. 24B and24D, it may also be desirable to locate the nut ratchet teeth 320 onlyunder the corners of the wrench bearing surfaces 314, since there isgreater radial space available under the corners for the ratchet teeth320. Preferably, the nut 310 has at least two teeth 320 so that if onetooth 320 fails there will still be one tooth 320 available for locking.Alternatively, where the nut 310 has six wrench bearing surfaces 314,the nut 310 may have six ratchet teeth 320, with one tooth 320underneath each corner.

While preferred embodiments of the invention have been described, itshould be understood that the invention is not so limited, andmodifications may be made without departing from the invention. Thescope of the invention is defined by the appended claims, and alldevices that come within the meaning of the claims, either literally orby equivalence, are intended to be embraced therein. Furthermore, theadvantages described above are not necessarily the only advantages ofthe invention, and it is not necessarily expected that all of thedescribed advantages will be achieved with every embodiment of theinvention.

The invention claimed is:
 1. A nut fastener, comprising: a retainingring comprising: a first rotational retaining member engageable with ashaft thereby preventing relative rotation between said retaining ringand said shaft, a pressure surface adapted to apply longitudinal forceto an apparatus, a first spring abutment surface, a second springabutment surface, and a second rotational retaining member; a collarcomprising: a third rotational retaining member engaged with said secondrotational retaining member thereby preventing relative rotation betweensaid collar and said retaining ring, said second spring abutmentsurface, and a fourth rotational retaining member, a first springdisposed between said first spring abutment surface and said secondspring abutment surface, said first spring thereby biasing said collaraway from said retaining ring and said collar being longitudinallymoveable toward said retaining ring by compressing said first spring,and a second spring; a nut comprising: a third spring abutment surfaceengaged with a first torque bearing surface thereby translating alongitudinal force from said nut to said retaining ring, a fourth springabutment surface, a fifth rotational retaining member engageable withsaid fourth rotational retaining member thereby resisting relativerotation between said nut and said collar when said collar is biasedaway from said retaining ring by said first spring, and inner threadsengageable with external threads on said shaft, wherein a force appliedto said collar compresses said first spring between the first and thirdspring abutment surfaces and moves said collar toward said retainingring, said fourth rotational retaining member and said fifth rotationalretaining member thereby disengaging from each other to allow relativerotation between said nut and said collar, wherein said second spring isdisposed between said second abutment surface and said fourth springabutment surface, said second spring thereby biasing said nut away fromsaid retaining ring and said nut being longitudinally moveable towardsaid retaining ring and said collar by compressing a third spring,wherein a bias of said first spring is greater than a bias force of saidsecond spring, wherein said bias force of said first spring is at leasttwo times greater than said bias force of said second spring.
 2. The nutfastener of claim 1, wherein said retaining ring includes a firstlongitudinal retaining member, wherein said nut comprises a secondlongitudinal retaining member engaged with said first longitudinalretaining member thereby preventing said nut and said retaining ringfrom separating from each other, wherein said retaining ring comprises athird longitudinal retaining member and said collar comprises a fourthlongitudinal retaining member, said fourth longitudinal retaining memberengaged with said third longitudinal retaining member thereby preventingsaid collar and said retaining ring from separating from each other,wherein a first spacing between said fifth rotational retaining memberand said second longitudinal retaining member of said nut and a secondspacing between said fourth rotational retaining member and said fourthlongitudinal retaining member of said collar is sized relative theretosuch that said fourth and fifth rotational retaining members aredisengaged from each other when said first and second longitudinalretaining members are engaged and said third and fourth longitudinalretaining members are engaged, said nut thereby free spinning relativeto said collar during initial threading of said nut onto said shaft, andadditional threading of said nut onto said shaft as said retaining ringapplies force to said apparatus draws said fourth and fifth rotationalretaining members into engagement with each other.
 3. The nut fastenerof claim 1, wherein said retaining ring further comprises a secondspring disposed between said third spring abutment surface and saidfourth spring abutment surface, said second spring thereby biasing saidnut away from said retaining ring and said nut being longitudinallymoveable toward said retaining ring and said collar by compressing saidsecond spring.
 4. The nut fastener of claim 3, wherein said first springand said second spring are both circular springs disposed around an axisof said nut fastener.
 5. The nut fastener of claim 3, wherein a biasforce of said first spring is greater than a bias force of said secondspring, wherein said bias force of said first spring is at least twotimes greater than said bias force of said second spring.
 6. The nutfastener of claim 1, wherein at least one of said fourth and fifthrotational retaining members is a ratchet tooth with a first inclinedsurface and a second inclined surface, engagement between said fourthand fifth rotational retaining members along said first inclined surfacebiasing said collar toward said retaining ring to allow relativerotation between said nut and said collar in a tightening direction, andengagement between said fourth and fifth rotational retaining membersalong said second inclined surface biasing said collar toward saidretaining ring to allow relative rotation between said nut and saidcollar in a loosening direction, said second inclined surface having asteeper incline than said first inclined surface such that said fourthand fifth rotational retaining members have greater resistance torelative rotation in said loosening direction than said tighteningdirection.
 7. The nut fastener of claim 6, wherein a resistance betweensaid fourth and fifth rotational retaining members in said tighteningdirection is high enough to require said tool to tighten said nut whensaid fourth and fifth rotational retaining members are fully engaged,wherein a resistance between said fourth and fifth rotational retainingmembers in said loosening direction is at least three times saidresistance in said tightening direction.
 8. The nut fastener of claim 6,wherein said fourth and fifth rotational retaining members each comprisea ratchet tooth, each of said ratchet teeth comprising one of said firstinclined surface and one of said second inclined surface, wherein bothof said second inclined surfaces of the fourth and fifth rotationalretaining members have steeper inclines than both of said first inclinedsurfaces of said fourth and fifth rotational retaining members.
 9. Thenut fastener of claim 1, wherein said collar further comprises alongitudinal portion extending toward said retaining ring, wherein aninner surface of said longitudinal portion encompasses said entire outercircumference of said retaining ring, wherein no portion of saidretaining ring extends out from said inner surface of said longitudinalportion.
 10. The nut fastener of claim 1, wherein said collar comprisesan engagement surface, a longitudinal force applied to said engagementsurface by said tool when loosening said nut compressing said firstspring to move said collar toward said retaining ring and at leastpartially disengaging said fourth and fifth rotational retainingmembers.
 11. The nut fastener of claim 10, wherein said engagementsurface is generally flush with a top of said fourth rotationalretaining member, said engagement surface being disposed adjacent abottom end of said wrench bearing surfaces when said fourth and fifthrotational retaining members are fully engaged, said engagement surfacethereby being engageable by an end of said tool when said tool engagessaid wrench bearing surfaces to apply said longitudinal force.
 12. Thenut fastener of claim 1, further comprising at least two of said fifthrotational retaining member, said fifth rotational retaining membersbeing disposed under corners between adjacent of said wrench bearingsurfaces.
 13. The nut fastener of claim 1, wherein said collar is astamping from a plate, said collar thereby having a generally uniformthickness.
 14. The nut fastener of claim 1, wherein said retaining ringincludes a first longitudinal retaining member, wherein said nutcomprises a second longitudinal retaining member engaged with said firstlongitudinal retaining member thereby preventing said nut and saidretaining ring from separating from each other, wherein said retainingring comprises a third longitudinal retaining member and said collarcomprises a fourth longitudinal retaining member, said fourthlongitudinal retaining member engaged with said third longitudinalretaining member thereby preventing said collar and said retaining ringfrom separating from each other, a first spacing between said fifthrotational retaining member and said second longitudinal retainingmember of said nut and a second spacing between said fourth rotationalretaining member and said fourth longitudinal retaining member of saidcollar being sized relative thereto such that said fourth and fifthrotational retaining members are disengaged from each other when saidfirst and second longitudinal retaining members are engaged and saidthird and fourth longitudinal retaining members are engaged, said nutthereby free spinning relative to said collar during initial threadingof said nut onto said shaft, and additional threading of said nut ontosaid shaft as said retaining ring applies force to said apparatus drawssaid fourth and fifth rotational retaining members into engagement witheach other.
 15. The nut fastener of claim 12, wherein at least one ofsaid fourth and fifth rotational retaining members is a ratchet toothwith a first inclined surface, engagement between said fourth and fifthrotational retaining members along said first inclined surface biasingsaid collar toward said retaining ring to allow relative rotationbetween said nut and said collar in a tightening direction.
 16. The nutfastener of claim 13, wherein said first spring and said second springare both circular springs disposed around an axis of said fastener, anda bias force of said first spring is at least four times greater than abias force of said second spring.
 17. The nut fastener of claim 1,wherein said retaining ring includes a first longitudinal retainingmember, wherein said nut comprises a second longitudinal retainingmember engaged with said first longitudinal retaining member therebypreventing said nut and said retaining ring from separating from eachother, wherein said retaining ring comprises a third longitudinalretaining member and said collar comprises a fourth longitudinalretaining member, said fourth longitudinal retaining member engaged withsaid third longitudinal retaining member thereby preventing said collarand said retaining ring from separating from each other, a first spacingbetween said fifth rotational retaining member and said secondlongitudinal retaining member of said nut and a second spacing betweensaid fourth rotational retaining member and said fourth longitudinalretaining member of said collar being sized relative thereto such thatsaid fourth and fifth rotational retaining members are disengaged fromeach other when said first and second longitudinal retaining members areengaged and said third and fourth longitudinal retaining members areengaged, said nut thereby free spinning relative to said collar duringinitial threading of said nut onto said shaft, and additional threadingof said nut onto said shaft as said retaining ring applies force to saidapparatus draws said fourth and fifth rotational retaining members intoengagement with each other, at least one of said fourth and fifthrotational retaining members is a ratchet tooth with a first inclinedsurface and a second inclined surface, engagement between said fourthand fifth rotational retaining members along said first inclined surfacebiasing said collar toward said retaining ring to allow relativerotation between said nut and said collar in a tightening direction, andengagement between said fourth and fifth rotational retaining membersalong said second inclined surface biasing said collar toward saidretaining ring to allow relative rotation between said nut and saidcollar in a loosening direction, said second inclined surface having asteeper incline than said first inclined surface such that said fourthand fifth rotational retaining members have greater resistance torelative rotation in said loosening direction than said tighteningdirection.
 18. The nut fastener of claim 16, wherein said first springand said second spring are both circular springs disposed around an axisof said nut fastener, a resistance between said fourth and fifthrotational retaining members in said tightening direction is high enoughto require said tool to tighten said nut when said fourth and fifthrotational retaining members are fully engaged, and a resistance betweensaid fourth and fifth rotational retaining members in said looseningdirection is at least three times said resistance in said tighteningdirection, said collar is a stamping from a plate, said collar therebyhaving a generally uniform thickness, said collar comprises a bentportion extending longitudinally toward said retaining ring, an innersurface of said bent portion encompassing an outer circumference of saidretaining ring, wherein said third rotational retaining member isdisposed along said bent portion and said second rotational retainingmember of said retaining ring is disposed along an outer surfacethereof, an inner surface of said bent portion encompasses said entireouter circumference of said retaining ring, wherein no portion of saidretaining ring extends out from said inner surface of said bent portion,and said first rotational retaining member is a tab engageable with aslot in said shaft.